U.S. patent number 5,369,147 [Application Number 08/224,775] was granted by the patent office on 1994-11-29 for cured unsaturated polyester-polyurethane hybrid highly filled resin foams.
This patent grant is currently assigned to Ecomat, Inc.. Invention is credited to John N. Mushovic.
United States Patent |
5,369,147 |
Mushovic |
* November 29, 1994 |
Cured unsaturated polyester-polyurethane hybrid highly filled resin
foams
Abstract
The present invention is directed to a rigid, lightweight filled
resin foam having voids dispersed in a continuous phase which is
formed from a polyester hybrid resin having reinforcing particles
dispersed therein. The hybrid resin forms a complex crosslinked
network which may interact with other polymer networks in the
continuous phase either by crosslinking or by forming an
interpenetrating polymer network. The present invention is also
directed to a process for preparing the above rigid, lightweight
resin foam, and to a composition for use in this process. The foam
of the present invention is useful in building materials and the
like requiring high tensile and compressive strength and corrosion
and thermal resistance.
Inventors: |
Mushovic; John N. (The Plains,
VA) |
Assignee: |
Ecomat, Inc. (Chantilly,
VA)
|
[*] Notice: |
The portion of the term of this patent
subsequent to April 12, 2011 has been disclaimed. |
Family
ID: |
27377634 |
Appl.
No.: |
08/224,775 |
Filed: |
April 8, 1994 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
|
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961332 |
Oct 15, 1992 |
5302634 |
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Current U.S.
Class: |
523/219; 523/218;
521/173; 521/172; 521/137; 521/123; 521/54; 521/122 |
Current CPC
Class: |
C08G
18/68 (20130101); C08J 9/0066 (20130101); B29C
44/3446 (20130101); C08J 9/32 (20130101); C08G
2110/0025 (20210101); C08G 2270/00 (20130101); C08J
2375/06 (20130101); C08J 2375/04 (20130101) |
Current International
Class: |
B29C
44/34 (20060101); C08G 18/00 (20060101); C08G
18/68 (20060101); C08J 9/32 (20060101); C08J
9/00 (20060101); C08J 009/32 () |
Field of
Search: |
;523/219,218
;521/122,123,137,172,173,54 |
References Cited
[Referenced By]
U.S. Patent Documents
Other References
Edwards, "The Application of Isophthalic Unsaturated . . . " 42nd
Annual Conference Composite Institute, Feb. 2-6, 1987, pp. 1-6,
Session 8-C, The Society of The Plastics Industry Inc. .
"Interpol 5118", Cook Composites and Chemicals, Inc. .
"Interpol 5124", Cook Composites and Chemicals, Inc. .
"Interpol 5116", Cook Composites and Chemicals, Inc. .
Aluminum Company of America, Material Safety Data Sheet for "Red
Mud". .
Newsfocus, Industry and Newsfocus, Technology Plastics Technology,
Dec. 1992, pp. 14 and 74. .
American Electric Power Service Corporation National Safety Data
Sheet (Fly Ash). .
K. Ashida, Polyisocyanurate Foams, Preparation of Modified
Polyisocyanurate Foams, vol. 6, pp. 112-124. .
F. A. Shutov, Hollow Sphere Fillers, Syntactic Polymer Foams, vol.
16, pp. 356-359. .
Sample Resin Formulations, Formulating Hybrid Resin Molding
Compounds, Formulating Hydroxyl-Terminated Unsaturated
Isopolyesters, What are Hybrid Resins?..
|
Primary Examiner: Foelak; Morton
Attorney, Agent or Firm: Birch, Stewart, Kolasch &
Birch
Parent Case Text
The present application is a continuation-in-part of Ser. No.
07/961,332, filed Oct. 15, 1992 now U.S. Pat. No. 5,302,634.
Claims
What is claimed is:
1. A rigid, lightweight filled resin foam, comprising:
(A) a continuous phase having cellular voids therein, wherein said
continuous phase comprises a matrix formed from a complex
crosslinked network comprising an unsaturated polyester
polyurethane resin which is the reaction product of an unsaturated
polyester polyol, a saturated polyol, a poly- or diisocyanate, and
a reactive monomer, and optionally further comprising:
(1) polyurethane modified hybrid networks;
(2) networks of polymerization products of reactive monomers;
(3) networks of polymerization products of saturated polyester
polyol and poly- or diisocyanates;
(4) other networks that may form during the formation of the
polyester polyurethane resin; or
(5) mixtures of the above networks; and
(B) fine multisize reinforcing particles dispersed in said matrix
of said continuous phase, wherein the diameter of the largest of
said multisize particles is no greater than about 33% of the
average thickness of said walls between said cellular voids, and
wherein at least a portion of said multisize particles are capable
of containing and releasing a blowing agent during the formation of
said polyester polyurethane resin.
2. The rigid, lightweight filled resin foam according to claim 1,
wherein said unsaturated polyester polyurethane resin has been at
least partially crosslinked with a reactive monomer.
3. The rigid, lightweight filled resin foam according to claim 1,
wherein said unsaturated polyester polyurethane resin has been at
least partially crosslinked with poly- or diisocyanate.
4. The rigid, lightweight filled resin foam according to claim 1,
wherein said matrix comprises an interpenetrating polymer
network.
5. The rigid, lightweight filled resin foam according to claim 1,
wherein said matrix further comprises a polyurethane network
obtained by the reaction of a diisocyanate or polyisocyanate with a
saturated polyester polyol.
6. The rigid, lightweight filled resin foam according to claim 1,
wherein said matrix further comprises a modified polyurethane
hybrid resin obtained by the reaction of a polyisocyanate, an
unsaturated polyester polyol, a saturated polyester polyol, and
styrene monomer in the presence of a free radical initiator.
7. The rigid, lightweight filled resin foam according to claim 1,
wherein said continuous phase further comprises a flame
retardant.
8. The rigid, lightweight filled resin foam according to claim 5,
wherein said flame retardant comprises a halogenated diol or
polyol.
9. The rigid, lightweight filled resin foam according to claim 1,
wherein said reinforcing particles having a particle size in the
range of submicron to 200 microns.
10. The rigid, lightweight filled resin foam according to claim 1,
wherein said multisize reinforcing particles are selected from the
group consisting of treated red mud, aluminum hydrates, feldspars,
clays, kaolinite, bentonite, beidellite, hydroxides, fly ash which
has been preloaded with a blowing agent, diatomaceous earth, broken
or cracked microballoons, broken or cracked microspheres,
cenospheres separated from fly ash, Fullers earth, wood flour, cork
dust, cotton flock, wool felt, shredded or finely powdered
cornstalks, finely ground nut shells, and mixtures thereof.
11. The rigid, lightweight filled resin foam according to claim 1,
wherein said multisize reinforcing particles are selected from the
group consisting of treated red mud, aluminum hydrates, feldspars,
clays, kaolinite, bentonite, beidellite, hydroxides, fly ash which
has been preloaded with a blowing agent, diatomaceous earth, broken
or cracked microballoons, broken or cracked microspheres,
cenospheres separated from fly ash, Fullers earth, cork dust,
cotton flock, wool felt, shredded or finely powdered cornstalks,
finely ground nut shells, and mixtures thereof.
12. The rigid, lightweight filled resin foam according to claim 1,
wherein said multisize reinforcing particles are selected from the
group consisting of treated red mud, aluminum hydrates, feldspars,
clays, kaolinite, bentonite, beidellite, hydroxides, and mixtures
thereof.
13. The rigid, lightweight filled resin foam according to claim 1,
wherein said reinforcing particles are selected from the group
consisting of diatomaceous earth, broken or cracked microballoons,
broken or cracked microspheres, cenospheres separated from fly ash,
Fullers earth, cork dust, cotton flock, wool felt, shredded or
finely powdered cornstalks, finely ground nut shells, and mixtures
thereof.
14. The rigid, lightweight filled resin foam according to claim 1,
further comprising mineral fillers, chopped glass, chopped polymer
fiber, directional or nondirectional glass fabrics, steel, finely
ground powdered rubber, or mixtures thereof.
15. The rigid lightweight filled resin foam according to claim 1,
further comprising a mineral filler selected from the group
consisting of silicate, asbestos, calcium carbonate, mica, barytes,
alumina, talc, carbon black, quartz, novaculite silica, garnet,
saponite, calcium oxide, and mixtures thereof.
16. A process for producing the rigid, lightweight filled resin
foam of claim 1, comprising:
(A) forming a reaction mixture, comprising mixing unsaturated
polyester polyol, a diisocyanate or polyisocyanate, a saturated
polyol, a reactive monomer, and a free radical initiator, with fine
multisize reinforcing particles, at least a portion of which
contain a blowing agent and are capable of releasing said blowing
agent to the reaction mixture;
(B) reacting, but not appreciably crosslinking, said reaction
mixture;
(C) simultaneously with said reaction, foaming said reaction
mixture in the presence of said blowing agent, to form a ductile,
lightweight filled resin foam, wherein said blowing agent is
released into the reaction system from said fine multisize
reinforcing particles; and
(D) hardening said ductile lightweight filled resin foam either
immediately, or at a future time, by crosslinking to a rigid filled
foam.
17. The process according to claim 16, wherein said saturated
polyol is a saturated polyester polyol.
18. The process according to claim 16, wherein said step (A)
further comprises mixing an organic diol or polyol into said
reaction mixture.
19. The process according to claim 16, wherein said blowing agent
is selected from the group consisting of water,
trichloromono-fluoromethane, dibromodifluoromethane,
dichlorodifluoro-methane, dichlorotetrafluoroethane,
monochlorodifluoro-methane, trifluoroethylbromide, dichloromethane,
methylene chloride, and mixtures thereof.
20. The process according to claim 16, wherein said blowing agent
comprises water.
21. The process according to claim 16, wherein the fine multisize
reinforcing particles hold water at different energy levels within
the particles, combine water with oxides to form a range of
reactive hydroxides, trap water in spongy, foamy cenospheres,
contain adsorbed water on diverse carbon particles, or influence
water release by organic residues, polycyclic aromatic
hydrocarbons, or polynuclear aromatic hydrocarbons.
22. The process according to claim 16, wherein said multisize
reinforcing particles are selected from the group consisting of
treated red mud, aluminum hydrates, feldspars, clays, kaolinite,
bentonite, beidellite, hydroxides, fly ash which has been preloaded
with a blowing agent, diatomaceous earth, broken or cracked
microballoons, broken or cracked microspheres, cenospheres
separated from fly ash, Fullers earth, wood flour, cork dust,
cotton flock, wool felt, shredded or finely powdered cornstalks,
finely ground nut shells, and mixtures thereof.
23. The process according to claim 16, wherein said multisize
reinforcing particles are selected from the group consisting of
treated red mud, aluminum hydrates, feldspars, clays, kaolinite,
bentonite, beidellite, hydroxides, fly ash which has been preloaded
with a blowing agent, diatomaceous earth, broken or cracked
microballoons, broken or cracked microspheres, cenospheres
separated from fly ash, Fullers earth, cork dust, cotton flock,
wool felt, shredded or finely powdered cornstalks, finely ground
nut shells, and mixtures thereof.
24. The process according to claim 16, wherein said blowing agent
is water and wherein said multisize reinforcing particles are
selected from the group consisting of treated red mud, aluminum
hydrates, feldspars, clays, kaolinite, bentonite, beidellite,
hydroxides, and mixtures thereof.
25. The process according to claim 16, wherein said multisize
reinforcing particles are selected from the group consisting of fly
ash which has been preloaded with a blowing agent, diatomaceous
earth, broken or cracked microballoons, broken or cracked
microspheres, cenospheres separated from fly ash, Fullers earth,
cork dust, cotton flock, wool felt, shredded or finely powdered
cornstalks, finely ground nut shells, and mixtures thereof.
26. The process according to claim 16, wherein said step (A)
further comprises mixing a flame retardant into said reaction
mixture.
27. The process according to claim 16, wherein said flame retardant
comprises a halogenated diol or polyol.
28. The process according to claim 16, wherein said step (A)
further comprises mixing a catalyst and surfactant into said
reaction mixture.
29. A composition for producing a rigid, lightweight filled resin
foam according to claim 1, comprising:
(A) an unsaturated polyester polyol
(B) a diisocyanate, polyisocyanate, or mixture thereof
(C) a reactive monomer
(D) a free radical initiator
(E) fine size reinforcing particles having a blowing agent
entrained therein, and capable of releasing said blowing agent
during a reaction forming a polyester polyurethane resin.
30. The composition according to claim 29, further comprising:
(F) a saturated polyester polyol.
31. The composition according to claim 29, wherein said blowing
agent is selected from the group consisting of water,
trichloromonofluoromethane, dibromodifluoromethane,
dichlorodifluoromethane, dichlorotetrafluoroethane,
monochlorodifluoromethane, trifluoroethylbromide, dichloromethane,
methylene chloride, and mixtures thereof.
32. The composition according to claim 29, wherein said blowing
agent is water.
33. The composition according to claim 29, wherein said reactive
monomer is selected from the group consisting of styrene monomers,
vinyl monomers, and mixtures thereof.
34. The composition according to claim 29, wherein said reactive
monomer is a styrene monomer.
35. The composition according to claim 29, wherein said free
radical initiator is selected from the group consisting of
azoisobutyronitrile and an organic peroxide.
36. The composition according to claim 35, wherein said free
radical initiator is benzoyl peroxide.
37. The composition according to claim 29, further comprising:
(G) a flame retardant or mixtures of flame retardants.
38. The composition according to claim 37, wherein said flame
retardant comprises a halogenated diol or polyol, or mixtures
thereof.
39. The composition according to claim 29, further comprising:
(H) an organic diol or polyol, or mixtures thereof.
40. The composition according to claim 29, further comprising (I) a
surfactant or mixture of surfactants.
41. The composition according to claim 29, further comprising (J) a
catalyst, or mixture of catalysts.
42. The composition according to claim 29, further comprising (K) a
coupling agent.
43. The rigid, lightweight filled resin foam produced by the
process of claim 16.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
Foamed recyclables are molded, lightweight, two-polymer structured
materials containing large amounts of industrial waste products.
The physical properties of the cured products are excellent when
compared to the properties of commercially available foams. The
industrial waste products are fines, or must be converted to fines,
prior to use in the foamed recyclable. The binder or glue that
encapsulates each particle and forms the cellular walls of the foam
is itself a unique, two-polymer thermoset that, when cured, allows
maximum physical property attainment through polymer design.
Molded or processed foamed recyclables of the present invention are
useful as, e.g., lightweight roofing materials (e.g., tiles or
slates), decorative or architectural products, outdoor products,
low cost insulation panels, fencing, lightweight, buoyant or
corrosion-resistant marine products, etc.
2. Discussion of Related Art
Hybrid resins are known, and are described in Edwards, The
Application Of Isophthalic Unsaturated Polyester Urethane Hybrids
In Conventional Molding Techniques, 42nd Annual Conference
Composites Institute, The Society Of The Plastics Industry, Inc.,
Feb. 2-6, (1987) (pp. 1-6, Session 8-C), U.S. Pat. No. 4,822,849,
U.S. Pat. No. 4,892,919 and U.S. Patent No. 5,086,084.
Interpenetrating polymer networks, or IPNs are also known. An IPN
is a material which consists of a pair of networks, at least one of
which has been synthesized and/or crosslinked in the presence of
the other. An IPN can be described as an intimate mixture of two or
more distinct crosslinked polymer networks that cannot be
physically separated. Interpenetrating polymer networks can be
classified into several categories. For example, when only one
polymer is crosslinked and the other is linear, the product is
called semi-IPN. U.S. Pat. No. 4,302,553 discloses two structurally
different crosslinked polymers, which when combined, form an IPN
structure. The IPN structure is comprised of the two different
crosslinking polymers which are permanently entangled with one
another and characterized in that no chemical interaction had
occurred between the individual networks. Interpenetrating polymer
networks are also described in U.S. Pat. No. 4,923,934 and U.S.
Pat. No. 5,096,640.
Foamed and/or cured foams of polymer resins, which may contain
inorganic fillers, are described in U.S. Pat. No. 2,642,403, U.S.
Pat. No. 3,697,456, U.S. Pat. No. 4,331,726, U.S. Pat. No.
4,725,632, U.S. Pat. No. 4,777,208, U.S. Pat. No. 4,816,503, U.S.
Pat. No. 4,216,294, U.S. Pat. No. 4,260,538, U.S. Pat. No.
4,694,051, and U.S. Pat. No. 4,946,876.
Despite this activity, the products produced by the prior art,
especially products of lightweight construction materials, do not
have sufficiently well-balanced properties with regard to
structural strength, as well as with regard to corrosion and
thermal resistance, and processing.
Preparation of foams of unsaturated polyesters useful in the
manufacture of lightweight building materials has been attempted
using a number of different techniques. However, a difficulty
encountered in attempts to produce unsaturated polyester foams is
the generation of gases so as to cause a uniform expansion of the
resin at ambient temperatures before any appreciable crosslinking
occurs. The present inventor has discovered that with a two polymer
system, a significant portion of the crosslinking and curing does
not have to occur immediately after the maximum amount of gases has
been released. Indeed, upon completion of the first polymer
reaction, the crosslinking reaction can be delayed for hours.
However, should appreciable crosslinking occur before maximum gas
release, the accompanying exothermic reaction will cause cracking
as the previously unreleased gases are generated thereby causing
stresses against a very rigid crosslinked structure which is unable
to further expand. Moreover, should the polyurethane reaction have
not occurred to a point sufficient to maintain the cell structures,
the gases will gradually escape, and the expanded resin will drop
back to its original state. The cured polymer will form much like a
standard resin casting, with little or no expansion.
Lightweight cementitious compositions are known in which the
desired weight reduction over concrete is achieved by the use of
lightweight aggregate. However, articles made from such materials
are brittle and possess tensile strengths which are low and limit
many practical applications. Also, the density range of lightweight
concretes is three times higher than the foam of the present
invention.
Low density rigid polyurethane modified-polyisocyanurate foams have
been widely used as insulative structural members. As with other
polymeric materials, it is often desirable to reduce the polymer
content and improve the properties of these members by the addition
of inorganic fillers. Unfortunately, it has proven difficult to
provide a rigid polyurethane or polyisocyanurate foam containing
more than about 10% by weight of such fillers. These fillers tend
to rupture the cells of the foam, which in turn dramatically
reduces its insulative capacity. Another undesirable effect of high
levels of fillers is that the foam becomes very friable. Since
higher filler levels are desired, because they provide a less
expensive material and certain physical property improvements, it
would be highly desirable to provide a highly filled, rigid
polyurethane-modified polyisocyanurate foam which has good
insulative properties and low friability.
U.S. Pat. No. 4,661,533 relates to using a particular inorganic
filler, namely fly ash, as the inorganic filler for filling rigid
polyurethane modified-polyisocyanurate foams. High percentage
additions of fly ash to very light weight (2 pounds per cubic foot
(pcf)) insulating foam are described. The use of the fly ash
inorganic filler enables the foam to be filled to a theoretical
level of about 80% of the foam's total weight without deterioration
of the insulative properties, friability and compressive strength.
The foam is useful as board insulation, sheathing insulation, pipe
insulation and the like. However, even though the foam of the above
patent is highly filled with fly ash, the problems associated with
the formation of two distinct polymers and hybrid resin technology
where a very high percentage of the end product is crosslinkable as
a cured polyester (up to 90%) did not have to be addressed.
Additionally, the superior processing advantages inherent in the
polyester/polyurethane chemistry are not possible with the prior
art product. The potential physical properties obtainable from the
filled foam of the present invention, having two distinct polymer
systems, are much higher, and the ability to control individual
reactions in the polyester/polyurethane system used in the present
invention is considerably better than that possible with the single
shot polyurethane/polyisocyanurate chemistry of the prior art.
SUMMARY OF THE INVENTION
An object of the present invention is to provide a low cost, rigid
lightweight polymeric cementitious composition, which has the
desirable physical and chemical properties, and processing
flexibility of traditional structural building materials.
Another object of the present invention is to provide highly filled
foamed thermosets having an overall improvement in structural
strength, corrosion and thermal resistance, and related properties,
and having excellent properties in the highly filled modification
of the curable foamable composition.
Another object of the present invention is to provide a foamed
building material which recycles and uses large quantities of
industrial waste particulates, thereby providing a low cost
building material, and decreasing disposal costs for these
industrial waste materials.
A particular object of the present invention is to provide a novel
unsaturated polyester polyurethane hybrid resin foam, which has a
continuous phase having cellular voids dispersed therein, formed
from a matrix comprising a complex crosslinked network of an
unsaturated polyester polyurethane resin, and having dispersed
therein fine multisize reinforcing particles at least a portion of
which are capable of releasing a blowing agent during the formation
of the polyester polyurethane resin network, thereby foaming the
reaction mixture and allowing for the development of unique, high
strength, highly-filled cell walls.
Another object of the present invention is to provide a process for
preparing the above rigid, lightweight filled resin foam, the
foaming reaction of which may be uniquely controlled, which can be
used with conventional, low cost processing equipment.
Another object of the present invention is to provide a rigid,
lightweight filled resin foam which can be effectively reinforced
with mineral fillers, chopped glass, chopped polymer fiber,
directional or nondirectional glass fabrics, steel, finely ground
powdered rubber, and the like, which take advantage of one or both
phases to provide this effective reinforcement.
These and other objects and advantages are obtained by the present
invention by providing a rigid, lightweight filled resin foam,
comprising:
(A) a continuous phase having cellular voids therein, wherein said
continuous phase comprises a matrix formed from a complex
crosslinked network comprising an unsaturated polyester
polyurethane resin which is the reaction product of an unsaturated
polyester polyol, a saturated polyol, a poly- or diisocyanate, and
a reactive monomer, and optionally further comprising:
(1) polyurethane modified hybrid networks:
(2) networks of polymerization products of reactive monomers;
(3) networks of polymerization products of saturated polyester
polyol and poly- or diisocyanates;
(4) other networks that may form during the formation of the
polyester polyurethane resin; or
(5) mixtures of the above networks; and
(B) fine multisize reinforcing particles dispersed in said matrix
of said continuous phase, wherein the diameter of the largest of
said multisize particles is no greater than about 33% of the
average thickness of said walls between said cellular voids, and
wherein at least a portion of said multisize particles are capable
of containing and releasing a blowing agent during the formation of
said polyester polyurethane resin.
The unsaturated polyester polyurethane resin may be at least
partially crosslinked with a reactive monomer, or a poly- or
diisocyanate, or both. The network formed by the polyester
polyurethane may be entangled with the other networks described
above (e.g., with a polyurethane network obtained by reaction of a
poly- or diisocyanate with a saturated polyester polyol, or with a
modified polyurethane hybrid resin obtained by reaction of a
polyisocyanate, an unsaturated polyester polyol, a saturated
polyester polyol, and styrene monomer in the presence of a free
radical initiator) to form an interpenetrating polymer network
(IPN), or may be crosslinked with these networks. Regions of both
IPN and crosslinking may occur in the same matrix. The continuous
phase may also contain a flame retardant, such as a halogenated
diol or polyol.
The fine multisize reinforcing particles may have a particle size
distribution in the range of submicron particles to sizes as large
as 200 microns, more particularly a range of 0.1 to 100 microns.
The particles may be selected from the group consisting of treated
red mud, aluminum hydrates, feldspars, clays, kaolinite, bentonite,
beidellite, hydroxides, fly ash which has been preloaded with a
blowing agent, diatomaceous earth, broken or cracked microballoons,
broken or cracked microspheres, cenospheres separated from fly ash,
Fullers earth, wood flour, cork dust, cotton flock, wool felt,
shredded or finely powdered cornstalks, finely ground nut shells,
and mixtures thereof.
The fine multisize reinforcing particles may be supplemented by
mineral fillers, such as silicate, asbestos, calcium carbonate,
mica, barytes, alumina, talc, carbon black, quartz, novaculite
silica, garnet, saponite, calcium oxide, and mixtures thereof, or
by chopped glass, chopped polymer fiber, directional or
nondirectional glass fabrics, steel, finely ground powdered rubber,
or mixtures thereof.
These objects are also obtained by providing a process for
producing the rigid, lightweight filled resin foam above,
comprising:
(A) forming a reaction mixture, comprising mixing unsaturated
polyester polyol, a diisocyanate or polyisocyanate, a saturated
polyol, a reactive monomer, and a free radical initiator, with fine
multisize reinforcing particles, at least a portion of which
contain a blowing agent and are capable of releasing said blowing
agent to the reaction mixture;
(B) reacting, but not appreciably crosslinking, said reaction
mixture;
(C) simultaneously with said reaction, foaming said reaction
mixture in the presence of said blowing agent, to form a ductile,
lightweight filled resin foam, wherein said blowing agent is
released into the reaction system from said fine multisize
reinforcing particles; and
(D) hardening said ductile lightweight filled resin foam either
immediately, or at a future time, by crosslinking to a rigid filled
foam.
The saturated polyol may be a saturated polyester polyol, and
organic diols or polyols may also be added to the reaction mixture
in step (A) to help form additional polymer networks. Flame
retardants, such as those described above, may also be added in
step (A). Catalysts and surfactants may also be added in step
(A).
The fine multisize reinforcing particles may contain a variety of
blowing agents, selected from the groups consisting of water,
trichloromono-fluoromethane, dibromodifluoromethane,
dichlorodifluoromethane, dichlorotetrafluoroethane,
monochlorodifluoromethane, trifluoroethylbromide, dichloromethane,
methylene chloride, and mixtures thereof.
When the blowing agent is water, the fine multisize reinforcing
particles may contain combined water by holding the water at
different energy levels within the particles, combining the water
with oxides to form a range of reactive hydroxides, trapping water
in spongy, foamy cenospheres, containing water adsorbed on diverse
carbon particles, or influencing water release by organic residues,
polycyclic aromatic hydrocarbons, or polynuclear aromatic
hydrocarbons.
These objects are also obtained by providing a composition for
producing a rigid, lightweight filled resin foam comprising:
(A) an unsaturated polyester polyol
(B) a diisocyanate, polyisocyanate, or mixture thereof
(C) a reactive monomer
(D) a free radical initiator
(E) fine size reinforcing particles having a blowing agent
entrained therein, and capable of releasing said blowing agent
during a reaction forming a polyester polyurethane resin.
This reactive composition may also contain (F) a saturated
polyester polyol, (G) a flame retardant or mixture thereof, (H) an
organic diol or polyol, or mixture thereof, (I) a surfactant or
mixture thereof. (J) a catalyst or mixture of catalysts, or (K) a
coupling agent.
The reactive monomer may be selected from the group consisting of
styrene monomers, vinyl monomers, and mixtures thereof. The free
radical initiator may be selected from the group consisting of
azoisobutyronitrile and an organic peroxide, such as benzoyl
peroxide.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1A illustrates a fragmentary sectional view of a cellular
structure with particle diameters much smaller than the cell wall
thickness, as in the present invention.
FIG. 1B is the magnified circled region of particles and
binder.
FIG. 2A illustrates a fragmentary sectional view of a cellular
structure where the particle diameters are much larger than the
cell wall thickness, and is not part of the present invention.
FIG. 2B is the magnified circled region of voids and pure polymer
cell walls.
FIG. 3A illustrates a fragmentary sectional view of a cellular
structure where the particle diameters are equivalent to the cell
wall thickness, which is not part of the present invention.
FIG. 3B is the magnified circled region showing voids, particles,
and binder.
FIG. 4 illustrates a fragmentary sectional view of a cellular
structure showing the progressive depletion of void space in the
cell walls, obtained by mixing the optimal sizes and weight
percents of each size of particle, according to the present
invention. It also shows how the reinforcement level can be
maximized and excellent beam strength in the cell wall can be
maintained by the present invention.
FIG. 5A is a fragmentary magnified sectional view of the foamed
structure of the present invention.
FIG. 5B is a highly magnified sectional view of a cell wall of the
present invention.
FIG. 5C is a schematic representation of the hybrid molecular
structure of the present invention.
FIG. 5D is a schematic representation of a modified hybrid
molecular structure of the present invention.
FIG. 5E is a schematic representation of an IPN structure of the
present invention.
FIG. 6 is a fragmentary magnified schematic cross section of a clay
structure of treated red mud.
DETAILED DESCRIPTION OF THE INVENTION
FIGS. 1A, 1B, 2A, 2B, 3A, and 3B show general cases of possible
resin, void, and filler combinations. The best properties of a
filled foam structure will occur when the cell walls contain filler
(12) and binder (13) such that the cell wall thickness is equal to
at least three, preferably at least four, reinforcing particle
diameters. Preferably the particles are spherical, so that the
surface area to volume ratio is as high as possible, maximizing
binder particle surface area contact, and avoiding stress riser
points in the cell wall.
FIG. 1A shows a foamed structure where the cell walls (10) between
the voids (11) are at least three particle (12) diameters
thick.
FIG. 2A shows a structure where the particles (12) are many times
larger than the voids (11), and where there are no particles in the
cell walls (10). The filler does not reinforce the cell walls, or
beams (10), as in the case of FIG. 1. In FIG. 2A the large
particles (12) are randomly dispersed in a matrix of pure polymer
cell walls (10) and voids (11). The physical properties of the
composite, including compressive and tensile strength, are equal to
or less than those achieved with the pure, unfilled foam of the
binder polymer. Other drawbacks to this structure include
unfavorable shear plane orientations, gravity influenced particle
distribution, shrinkage voids between filler particles, and long
corrosion paths into the foamed structure.
FIG. 3A also represents a structure with physical properties well
below those of the pure foam. In this case, the voids (11) have
grown to the point where the thickness of the cell wall (10) is
either one or two particle diameters thick. Again, the influence of
the filler orientation results in thin separating walls, having low
beam strengths, the tendency for more stress riser influence on the
cell walls, etc. As a result, the physical properties, thermal
insulating properties, and corrosion resistance are all low.
To obtain optimum properties in a foamed structure made up of
particles and binder, Applicant has discovered that there is an
optimum relationship between reinforcing particle size and shape,
void size, wall thickness, and the wall thickness to particle
diameter ratio. FIGS. 1B, 2B, and 3B schematically illustrate
this.
FIG. 4 illustrates a highly magnified sectional view of a cellular
structure (14) showing the progressive depletion of interparticle
void space (15) in the cell walls (not desirable void as 11)
obtained by mixing the correct sizes and weight percents of each
size of particles (12). Inscribed within the cell walls are circles
labeled (16), (17), and (18). These circles contain one size (16)
of spherical particles (12), two sizes (17) of spherical particles
(12), and, three or more sizes (18) of spherical particles (12),
which are described as unimodal, bimodal, and tri or multimodal
filling, respectively. For efficient filling, the particle sizes
and weight percent of each size are related. Desirably, there are
at least three different particle sizes in the mix for maximum
packing density. The largest particle diameter is preferably seven
times larger than the intermediate particle diameter, which itself
is preferably seven times larger than the diameter of the smallest
particle. A preferably size distribution is approximately 64.3
weight percent of the largest size particles, 26.5 weight percent
of the mid-size particles, and 9.2 weight percent of the smallest
size particles. Another factor that may be optimized is the maximum
particle size. The measurements of the cell walls (10) in foams
according to the present invention average 0.030 inches, which is
over four times the size of the largest particle in fly ash.
The most desirable physical properties are obtained when the rigid,
lightweight filled foam has a structure shown in the inscribed
circle (18), which structure is a part of the present invention.
This structure allows maximum filling, maximum beam strength,
maximum number of closed cells and excellent economics for any
non-directional filler or reinforcement particles. The particle
structure described by inscribed circle (18) also eliminates any
adverse effect on the properties of the foam due to the effects
discussed above with regard to FIGS. 2A, 2B, 3A, and 3B.
FIGS. 5A and 5B illustrate a fragmentary sectional view of the
current invention, and a highly magnified cross section of a cell
wall (10). FIG. 5A shows the continuous cell wall structure (10)
comprising the binder, with particles, and voids (11). FIG. 5B
shows highly magnified voids (11), and particles (12) that exhibit
multimodal packing in the cell wall (10) and the binder (13) which
encapsulates each particle and forms the polymer glue for the
complete structures.
FIGS. 5C, 5D, and 5E are molecular schematics depicting general
classes that the chemical structure takes in the current invention
and represent a hybrid, modified hybrid, and an IPN
(Interpenetrating Polymer Network) respectively. The hybrid
structure of FIG. 5C contains unsaturated polyester (21) linked to
polyurethane (19) by chemical bonds (20). The chains of unsaturated
polyester polyol/polyurethane are then crosslinked by the catalyst
initiated copolymerization of the polyurethane modified polyester
polymer units and the styrene monomer (22). FIG. 5D shows one of
the structures a reactive addition would produce. A reactive diol
(23) could either chain extend or crosslink chains to produce a
modified hybrid structure. FIG. 5D shows the hydroxyl containing
material linked to urethane segments (19) in each case. FIG. 5E
shows another structure that is produced. In this case there is no
chemical bonding between the strands of the urethane web (21). Each
network contains molecular bonding (20) sites comprising both chain
extension and crosslinking, and although the two networks are not
bonded to each other, there is sufficient entanglement to prevent
phase separation.
FIG. 6 is highly magnified cross sectional schematic of a typical
well crystallized clay found in processed red mud. Alternating
layers (24) contain erosion products which are typically rounded
and chemically contain oxides of silicon and aluminum. In the
treated red mud used in the present invention, there are several
varieties of clay, wherein the composition of layers (24) and the
metal ions (26) in alternate layers differ, thereby holding the
layers (24) together at different strengths and trapping the water
(25) at various levels of structure bonding strength, which require
a range of levels of heat energy to be applied to release water to
the curing and foaming stages of the process for preparing the
rigid, lightweight foams of the present invention.
The present invention relates to maximizing the properties of
highly filled foamed thermosets. More specifically it relates to
combinations of fillers, additives, and polymer chemistries that
produce a highly filled foamed structure having excellent
properties. These properties are the result of three innovative
approaches to the design of a filled foam structure. The approaches
are (1) correlating the type, relative sizes, and, weight percent
of each size of reinforcing particle with geometric considerations,
in the foam structure, thereby allowing the maximum filling rate in
the cell walls without destroying the structural integrity of the
wall; (2) efficiently using additives, which may accomplish two or
more functions as part of the reinforcing particle additive, and
blend chemistry system; and (3) using unique, state of the art,
two-polymer chemistry techniques to form a complex binding agent
for the reinforcing particles, thereby providing polymer
strengthening mechanisms within the confines of the cell walls, and
allowing an increase in processing flexibility not present in
single polymer systems.
The typical mineral filler for thermoplastic and thermoset polymers
is normally characterized as a chemically pure, homogeneous solid
with a narrow particle size distribution. In contrast, the
reinforcing particles used in the present invention may have
diverse chemical compositions and should have a wide range of
particle sizes.
The reinforcing particles used in the present invention may be any
particles that will reinforce the cell walls of the foamed
material, as more particularly described below, and which are
capable of entraining a blowing agent, either through chemical or
physical interactions, and of releasing the blowing agent during
the foaming reaction, also more particularly described below.
Desirably, the reinforcing particles possess, or are ground to
possess, a particle size distribution similar to that of fly ash or
treated red mud, i.e., of submicron to 200 microns, more
particularly 0.1 to 100 microns.
These reinforcing particles may be selected from treated red mud,
aluminum hydrates, feldspars, clays, kaolinite, bentonite,
beidellite, hydroxides, such as calcium hydroxide, or any particle
having a particle size distribution similar to that of red mud, and
capable of releasing water at various energy levels during the
reaction forming the continuous phase matrix, as more particularly
described below. Mixtures of these particles may also be used.
The reinforcing particles may also be selected from fly ash which
has been preloaded with a blowing agent, diatomaceous earth, broken
or cracked microballoons, broken or cracked microspheres,
cenospheres separated from fly ash, Fullers earth, wood flour, cork
dust, cotton flock, wool felt, shredded or finely powdered
cornstalks, finely ground nut shells, and other fine size cellular
materials having a particle size distribution similar to that of
fly ash. Mixtures of these particles may also be used.
Particles such as diatomaceous earth, broken or crushed
microballoons, broken or crushed microspheres, cenospheres
separated from fly ash, Fullers earth, and wool felt should be
preloaded with a blowing agent before reaction, as is done with fly
ash. Particles such as wood flour, cork dust, cotton flock,
shredded or finely powdered cornstalks, or finely ground nut shells
already contain water entrained therein, and may be used as is, or
after preloading with additional blowing agent.
Moreover, mixtures of particles from each of the above groups may
be used. The reinforcing particles are desirably selected from the
group consisting of treated red mud, preloaded fly ash, and
mixtures thereof.
Fly ash is a very fine ash produced by the combustion of powdered
coal with forced draft, which results in a mixture of alumina,
silica, unburned carbon, and various metallic oxides. Fly ash can
be described as heterogeneous fine powders consisting mostly of
rounded or spherical particles of variable silica, alumina, and
iron oxide content. The particle size range of the glassy spheres
is in the range of submicron to 200 microns in diameter, more
particularly 0.1 to 100 microns in diameter.
Typically, fly ash is a light brown, black or gray powder having no
odor. The chemical composition of fly ash generally comprising in a
major portion SiO.sub.2, Al.sub.2 O.sub.3 and Fe.sub.2 O.sub.3, and
in a minor portion CaO, MgO, NaO, K.sub.2 O, SO.sub.3 and
TiO.sub.2.
Fly ash is generally available as a waste byproduct of large-scale
coal fueled power generation plants. In addition, fly ash is
available from processes for gasifying coal. The chemical
composition of fly ash is dependent upon the coal source, and the
methods for burning the coal and collecting the fly ash. The
properties of fly ash are a function of the composition of the
coal, the particle size of the fly ash, and the temperature of
combustion.
Fly ash of Types C and F may be preloaded with blowing agent to
foam the continuous matrix, with Type F fly ash being preferred for
the present invention. Type F fly ash contains a much higher
percentage of hard particles (e.g., quartz, silicon dioxide,
aluminum oxide, and iron oxide) than Type C fly ash, a distinction
implicit in the definition of these types of fly ash. In addition,
these types of fly ash contain compositional differences. Type C
fly ash usually contains much higher amounts of magnesium oxide and
calcium oxide than does Type F fly ash. As a result of these
differences, some reinforcing capacity may be lost and chemical
changes may occur with Type C fly ash to a degree not associated
with Type F fly ash. These considerations will usually result in
Type F fly ash being more desirable for use in the present
invention.
Certain Type F fly ashes are more effective in the present
invention. While not wishing to be bound by any theory, it is
believed that the more effective Type F fly ashes lack a compound
that chemically interacts with one or more of the reactions taking
place in the polymer matrix of the continuous phase, thereby
delaying or impairing certain crosslinking reactions related to the
reactive monomer. The composition and physical properties of a
particularly effective Type F fly ash are set forth below in Table
1.
TABLE 1 ______________________________________ Constituent
Composition, % ______________________________________ Silicon
Dioxide, SiO.sub.2 60.1 Aluminum Oxide, Al.sub.2 O.sub.3 28.9 Iron
Oxide, Fe.sub.2 O.sub.3 3.4 Titanium Dioxide, TiO.sub.2 1.6
Phosphorus Pentoxide, P.sub.2 O.sub.5 0.10 Calcium Oxide, CaO 0.80
Magnesium Oxide, Mgo 0.80 Sodium Oxide, Na.sub.2 O 0.20 Potassium
Oxide, K.sub.2 O 2.60 Sulfur Trioxide, SO.sub.3 0.90 Total 99.6,
with 92.4% ______________________________________ composed of
silicon dioxide, aluminum oxide, and iron oxide. The physical
properties of this Type F fly ash include 0.70% loss on ignition,
and a pH of 5.5.
The fly ash component is generally employed in a proportion ranging
from about 15 to 80 parts, preferably about 50 to about 60 parts,
by weight per 100 parts by weight based on the total weight of the
curable foamable composition.
The fly ash or red mud may be partially substituted by other
fillers which include, but are not limited to, silicate, asbestos,
calcium carbonate, mica, barytes, alumina, talc, carbon black,
quartz, novaculite silica, garnet, saponite, calcium oxide, and
mixtures thereof.
Red mud, or bauxite residue, comprises impurities, in the form of
very fine particles, which are released from bauxite during the
production of alumina by the Bayer process. Red mud is a very wet,
alkaline, reddish brown heterogeneous substance which appears and
feels like red clay. The red mud is comprised of various clays,
which in turn may comprise silica, alumina, and minor amounts of
other oxides. Red mud comprises layered structures of these oxides
held together by other layers containing metal ions and combined
water. In order for red mud to be useful in the present invention,
both as a reinforcing particle and as a blowing agent source, the
red mud must be treated. Said treatment comprises driving off free
water at a prescribed temperature, and then pulverizing and
screening the dried red mud. The end result is a multi-particle
size red powder comprising a number of minerals, including clays
and oxides, and entrained water.
The red mud component of the present invention is generally
employed in a proportion ranging from about 15 to 80 parts,
preferably about 50 to 60 parts, per 100 parts by weight based on
the total weight of the curable foamable composition of the present
invention.
In general, the rigid lightweight filled resin foams of the present
invention may be foams that are predominantly open-cell,
predominantly closed cell, or contain approximately equivalent
amounts of open-cells and closed-cells. In general, larger and more
angular particles, such as treated red mud, tend to rupture growing
cell walls to a much greater extent than finer, more rounded
particles, such as fly ash. Accordingly the type of cells can be
controlled to a great extent by the selection of physical
properties of the filler particles. Moreover, surfactant evaluation
has shown that the material of the present invention behaves in a
manner similar to that of other foamed polymers with respect to
cell control. As a result, the nature of the cells of the product
of the present invention can be varied by varying the chemical
composition of the polymer phase and/or the foaming conditions in
ways known to those skilled in this art, and/or by varying the
physical characteristics of the filler particles.
As pointed out above, a mixture of fly ash and treated red mud may
be used in the curable foamable composition of the present
invention. The mixture is generally used in amounts of 15 to 85
parts, preferably 50 to 60 parts, by weight per 100 parts of the
total composition. The relative proportions of these two components
in the mixture may be varied in order to vary the reaction rate,
and to help vary the relative proportions of open and closed
cells.
The reinforcing particles may be supplemented by mineral fillers,
chopped glass, chopped polymer fiber, directional or nondirectional
glass fabrics, steel, finely ground powdered rubber, or the like.
Mineral fillers and powdered rubber should be ground to a particle
size distribution consistent with that of the reinforcing
particles, such as the particle size distribution of fly ash or
treated red mud.
The continuous phase of the rigid, lightweight filled resin foam
according to the present invention forms the walls of the void
spaces of the foam, and serves as a binder for the reinforcing
particles discussed above. This continuous phase comprises at least
an unsaturated polyester polyurethane hybrid resin, which forms a
matrix comprising a complex cross-linked network. The polyester
polyurethane hybrid resin is formed by reacting an unsaturated
polyester polyol, a saturated polyol, a poly- or diisocyanate, and
a reactive monomer, as shown in more detail below, and may be
crosslinked with either said reactive monomer or said poly- or
diisocyanate, or both. This reaction mixture may form additional
networks which may become entangled -or crosslinked with the
polyester polyurethane hybrid network, and thus incorporated into
the continuous phase network. As a result, the continuous phase may
also comprise, as exemplary networks, polyurethane modified hybrid
networks, or networks formed from polymerization products of
reactive monomers, or networks formed from polymerization products
of a saturated polyol with a poly or diisocyanate, or other
networks that may form during the above-described reaction, or
mixtures of any or all of these networks.
These networks may individually immobilize the reinforcing
particles discussed above. Alternatively, when multiple networks
are present they may be entangled, crosslinked together, or
otherwise interact, further immobilizing the reinforcing particles.
For example, the crosslinked polyester polyurethane hybrid resin
network may form an interpenetrating polymer network, or IPN, with
a second polyurethane network formed by the reaction of a
diisocyanate or polyisocyanate with a saturated polyester polyol.
Furthermore, the above-mentioned crosslinked hybrid resin may form
a modified IPN with said second polyurethane network and with a
third modified hybrid network formed by the reaction of a
diisocyanate or polyisocyanate, an unsaturated polyester polyol, a
saturated polyester polyol, and a reactive monomer.
As pointed out above, the polyester polyurethane hybrid resin
network may be entangled with other polymer networks to form an
interpenetrating polymer network, or IPN. An IPN is a material
which consists of a pair or networks, at least one of which has
been synthesized and/or crosslinked in the presence of the other.
Interpenetrating polymer networks (IPN) are more or less intimate
mixtures of two or more distinct crosslinked polymer networks that
cannot be physically separated. IPN can be considered as another
technique, very much like graft or block copolymerization, for
inducing polymer blend compatibility through polymer structure
modification. The possibility of combining various chemical types
of polymeric networks has produced IPN compositions that exhibit
synergistic behavior. If one polymer is elastomeric in nature and
another is glassy, then a reinforced rubber is obtained if the
elastomer phase predominates, and an impact-resistant plastic
results if the glassy phase predominates.
There are several categories of interpenetrating polymer networks.
When only one polymer is crosslinked and the other is linear the
product is called a semi-IPN. Semi-IPN or semi-2-IPN exists when,
respectively, polymer 1 or polymer 2 is the crosslinked component.
Furthermore, in addition to IPN - the general term for
interpenetrating polymer network - there can be distinguished the
simultaneous interpenetrating network (SIN), wherein both polymers
are synthesized simultaneously, by either addition or condensation
polymerization reactions, and the interpenetrating elastomeric
network (IEN). An IEN refers to those materials that are made by
mixing and coagulating two different polymer latexes, and
crosslinking the coagulum to form a three-dimensional structure. If
the latex coagulum is not crosslinked, the resulting product is
called a latex polyblend.
In the continuous phase of the present invention, although normally
crosslinking is present within each phase, in areas where a true
IPN exists, there is no polyurethane to polyester crosslinking.
This area of the foam is called an IPN (interpenetrating polymer
networks) structured composite. IPNs are formed when polymerization
compositions are independently reacted to form distinct,
intertwining, continuous polymeric chains. Chemically combining
different types of polymeric networks results in the formation of
resins having different properties. The IPN which is produced
exhibits properties that are different from the individual
constituent polymers.
As discussed above, an IPN may form in the foam of the present
invention by the reaction of the unsaturated polyester polyol,
which has hydroxy terminal groups, with a diisocyanate and/or
polyisocyanate and a reactive monomer, which crosslinks the
resulting polyester-polyurethane chain, and the independent
reaction of a saturated polyester polyol with said diisocyanate
and/or polyisocyanate to form a polyurethane. A modified hybrid IPN
may also form in the foam of the present invention when, in
addition to the above reactions, said diisocyanate and/or
polyisocyanate forms an additional network by reaction with said
unsaturated polyester polyol, said reactive monomer, and said
saturated polyester polyol. This complex third network may
intertwine with one or both of the other two networks. Other, more
complex arrangements are also possible.
For example, crosslinking between networks may occur to various
degrees, and usable structures may be formed from networks having
minor degrees of crosslinking and significant entanglement, forming
IPN-like structures in that the networks are entangled, but also
contain some crosslinking. Usable structures may also be formed
from networks that have an extremely high degree of crosslinking,
e.g., between all of the polymer networks present. This is more
likely to occur with hybrid resins containing high functionality
polyisocyanates and saturated and unsaturated polyols having large
numbers of hydroxyl sites.
Hybrid resins are well-known in the art, and hybrid
polyester-polyurethane resins combine the best features of the
polyester and polyurethane technologies. The resins are tougher
than polyesters, and are stronger, stiffer and less costly than
polyurethanes. Unsaturated polyester-polyurethanes contain double
bonds which can react with styrene to form a strong, yet flexible
solid.
Urethane hybrids are also versatile, and can be formulated for use
in virtually any method of molding common to the unsaturated
polyester and urethane industries. Equally important, they can be
cured in a matter of seconds at room temperature or can be molded
at elevated temperatures. They can be of low viscosity for ease of
pumping or to embrace high levels of filler and reinforcement, or
they can be thickened to flow only under high pressures and
temperatures.
The weight percent range of polyurethane in the overall filled
polyester/polyurethane structure should be between 10% and 60%.
Below 10% the contribution of the urethane to the properties of the
structure is minimal, and the ability to foam the material is
considerably lessened. If the urethane percentage is over 60% some
polyester crosslinking reactions may be hindered, and manufacturing
consistency will be lost.
Unsaturated polyesters useful in forming the polyester
polyol-polyurethane hybrid resin are typically prepared as the
condensation reaction products of at least a di- or a polybasic
acid, or an anhydride thereof, and a di- or polyhydric compound,
wherein at least one of said acid or anhydride, or said di- or
polyhydric compound contains ethylenic unsaturation. Optionally,
flame retardant materials may be included as a reactant in the
formation of said unsaturated polyester.
The unsaturated polyesters of the present invention are generally
employed in a proportion ranging from about 20 to 80 parts,
preferably 40 to 70 parts, per 100 parts by weight based on the
total weight of the curable foamable composition, exclusive of the
weight of reinforcing particles.
Typical di- or poly-basic acids or anhydrides thereof used in the
preparation of the unsaturated polyesters include, but are not
limited to, phthalic acids, iso- or terephthalic acid, adipic acid,
succinic acid, sebacic acid, maleic acid, fumaric acid, citaconic
acid, chloromaleic acid, allylsuccinic acid, itaconic acid,
mesaconic acid, citric acid, pyromellitic acid, trimesic acid,
tetrahydrophthalic acid, thiodiglycollic acid, and the like. These
acids and anhydrides may be independently or jointly used.
Typical di- or polyhydric compounds used in the preparation of the
unsaturated polyesters include, but are not limited to ethylene
glycol, diethylene glycol, triethylene glycol, propylene glycol,
dipropylene glycol, glycerol, 2-butyn-1,4-diol, neopentyl glycol,
1,2-propanediol, pentaerythritol, mannitol, 1,6-hexanediol,
1,3-butylene glycol, 2-buten-1,4-diol, hydrogenated bisphenol A,
bisphenoldioxyethyl ether, bisphenoldioxypropyl ether, neopentyl
glycol and the like.
A variety of reactive monomers may be used. The reactive monomers
may be mixed in with the polymeric components of the composition of
the present invention in an amount sufficient to produce a
thermoset product. In general, the proportions employed range from
about 10 to 25 parts by weight, preferably 10 to 20 parts by weight
per 100 parts by weight based on the total weight of the curable
foamable composition exclusive of the weight of reinforcing
particles. Specific examples include, but are not limited to,
styrene, chlorostyrenes, methyl styrenes such as s-methyl styrene,
p-methyl styrene, vinyl benzyl chloride, divinyl benzene, indene,
allyl benzene unsaturated esters such as: methyl methacrylate,
methyl acrylate and other lower aliphatic esters of acrylic and
methacrylic acids, allyl acetate, vinyl acetate, diallyl phthalate,
diallyl succinate, diallyl adipate, diallyl sebacate, diethylene
glycol bis(allyl carbonate), triallyl phosphate and other allyl
esters, and vinyl toluene, diallyl chlorendate, diallyl
tetrachlorophthalate, ethylene glycol diacrylate, ethylene glycol
dimethacrylate, ethylene glycol diethacrylate, amides such as
acrylamides, vinyl chloride, and mixtures thereof. Among these
examples, styrene is preferred.
The isocyanate component of the curable foamable composition of the
present invention has a isocyanate functionality of two or more.
The isocyanate component may thus be a diisocyanate or
polyisocyanate. The diisocyanates or polyisocyanates of the present
invention are generally employed in a proportion ranging from about
5 to 40 parts, preferably 15 to 20 parts by weight, per 100 parts
by weight based on the total weight of the curable foamable
composition exclusive of weight of reinforcing particles.
The diisocyanates or polyisocyanates include aliphatic, alicyclic
and aromatic types. Representative examples include
2,4-tolylenediisocyanate, 2,6-tolylenediisocyanate,
1,6-hexamethylenediisocyanate, 4,4'-diphenylmethanediisocyanate,
4,4'-diphenyletherdiisocyanate, m-phenylenediisocyanate,
1,5-naphthalenediisocyanate, biphenylenediisocyanate,
3,3'-dimethyl-4,4'biphenylenediisocyanate,
dicyclohexylmethane-4,4'-diisocyanate, p-xylylenediisocyanate,
m-xylylenediisocyanate, bis(4-isocyanatophenyl) sulfone,
isopropylidene bis(4-phenylisocyanate), tetramethylene
diisocyanate, isophorone diisocyanate, ethylene diisocyanate,
trimethylene diisocyanate, propylene-1,2-diisocyanate, ethylidene
diisocyanate, cyclopentylene-1,3-diisocyanates, 1,2-,1,3- or
1,4-cyclohexylene diisocyanates, 1,3- or 1,4-phenylene
diisocyanates, polymethylene polyphenyleneisocyanates,
bis(4-isocyanatophenyl)methane, 4,4'-diphenylpropane diisocyanates,
bis(2-isocyanatoethyl) carbonate,
1-methyl-2,4-diisocyanatocyclohexane, chlorophenylenediisocyanates,
triphenylmethane-4,4',4"-triisocyanate, isopropyl
benzene-.alpha.-4-diisocyanate,
5,6-diisocyanatobutylbicyclo[2.2.1]hept- 2-ene, hexahydrotolylene
diisocyanate, 1-methoxyphenyl-2,4-diisocyanate
4,4',4"-triphenylmethane triisocyanate, polymethylene
polyphenylisocyanate, tolylene-2,4,6-triisocyanate,
4,4'-dimethyldiphenylmethane-2,2',5,5'-tetraisocyanate, and
mixtures thereof.
The curable foamable composition of the present invention may
optionally contain di- or polyhydric compounds, capable of reacting
with the isocyanate component to form polyurethanes.
The typical optionally contained di- or polyhydric compounds
include ethylene glycol, diethylene glycol, triethylene glycol,
propylene glycol, dipropylene glycol, glycerol, 2-butyn-1,4-diol,
neopentyl glycol, 1,2-propanediol, pentaerythritol, mannitol,
1,6-hexanediol, 1,3-butylene glycol, 2-buten-1,4-diol, hydrogenated
bisphenol A, bisphenoldioxyethyl ether, bisphenoldioxypropyl ether,
neopentyl glycol and the like and mixtures thereof.
Examples of curing catalyst include azo compounds such as
azoisobutyronitrile, and organic peroxides, such as tertiary-butyl
perbenzoate, tertiary butyl peroctoate, benzoyl peroxide, methyl
ethyl ketone peroxide, acetoacetic peroxide, cumene hydroperoxide,
cyccohexanone hydroperoxide, and dicumyl peroxide. Benzoyl peroxide
is preferred. The catalyst is used in an amount of 0.03 to 2.5
parts by weight, preferably 0.5 to 1.0 parts by weight, per 100
parts by weight based on the total weight of the curable foamable
composition, exclusive of the weight of reinforcing particles.
To accelerate the curing, a metal compound may be optionally added.
Examples include cobalt naphthenate, cobalt octanoate, divalent
acetylacetone cobalt, trivalent acetylacetone cobalt, potassium
hexanoate, zirconium naphthenate, zirconium acetylacetonate,
vanadium naphthenate, vanadium octanoate, vanadium acetylacetonate,
lithium acetylacetonate and combinations thereof. Other
accelerators include tertiary amines such as dimethylaniline,
diethylaniline and dimethyl-p-toluidine.
Catalysts which promote the formation of urethane linkages by
reaction of isocyanate groups and hydroxy groups include amine
compounds, such as triethylenediamine, N-methylmorpholine,
tetramethyl-1,4-butanediamine, N-methylpiperazine,
dimethylethanolamine, diethylethanolamine, triethylamine, and the
like; and organometallic compounds, such as stannous octanoate,
dibutyltin dilaurate, dibutyltin di-2-ethylhexanoate, and the like.
These may be used alone or in combination with one another. The
catalyst can be used in a broad range of amounts, usually 0.03 to
2.0 parts by weight, preferably 0.02 to 1.0 parts by weight, per
100 parts by weight based on the total weight of the curable
foamable composition, exclusive of the weight of reinforcing
particles.
The foaming or blowing agent which may be optionally added to the
curable foamable composition of the present invention includes
water or a low-boiling volatile liquid. Examples of low-boiling
volatile liquids are halogenated hydrocarbons which include
trichloromonofluoromethane, dibromodifluoromethane,
dichlorodifluoromethane, dichlorotetrafluoroethane,
monochlorodifluoromethane, trifluoroethylbromide, dichloromethane,
methylene chloride, and the-like. These may be used alone or in
combination with one another. Other conventional foaming or blowing
agents are also within the scope of this invention.
Fire retardant raw materials may optionally be included as a
reactant in the preparation of the unsaturated polyester polyol
component, of the polyurethane component, or of both.
Alternatively, these flame retardant raw materials may simply be
physically mixed and become part of a dispersed ingredient in the
composition of the present invention.
Fire retardant materials which may be used as reactants in the
preparation of the unsaturated polyesters include
tetrachlorophthalic anhydride, tetrabromophthalic anhydride,
dibromotetrahydrophthalic anhydride, chlorendic acid,
tetrabromobisphenol A, dibromoneopentyl glycol and the like. Said
fire retardant materials are preferably contained in a proportion
ranging from 5 to 40, preferably 5-20 parts by weight based on the
total weight of the curable foamable composition, exclusive of the
weight of the reinforcing particles.
The hybrid cured foam of the present invention may also contain
non-reactive halogen-containing material in a proportion ranging
from about 5 to 20 parts, preferably about 5 to 10 parts by weight,
per 100 parts by weight based on the total weight of the curable
foamable composition exclusive of the weight of reinforcing
particles. These non-reactive halogen-containing materials include
organic and/or inorganic materials. The organic materials include
halogenated aliphatic, cycloaliphatic, cyclic and aromatic
hydrocarbons. Illustrative are tetrachlorobutane, tetrabromobutane,
hexabromoethane, chlorendic anhydride, tetrahalogenated phthalic
anhydride, tetrabromocyclooctane, tetrachlorocyclooctane,
hexachlorocyclopentadiene, hexabromocyclododecane,
hexachlorocyclododecane, hexabromocyclohexane, pentabromotoluene,
and the halogenated bi- and polyphenyl aromatic compounds.
Halogenated polymeric materials are also useable. Inorganic
materials include metal oxides, such as antimony oxides, iron
oxides, copper oxides, titanium oxides and mixtures thereof.
Illustrative examples include antimony trioxide, antimony
tetraoxide, antimony pentoxide, ferric oxide, cupric oxide,
titanium dioxide, etc.
Coupling agents, such as silanes or titanates, may also be included
in the preparation of the rigid lightweight foams of the present
invention to improve the physical properties of the foam by binding
the hybrid resin more strongly to the reinforcing particles.
The present invention is additionally directed to methods for
pretreating the various foamable composition components, methods
for producing the foam, and methods for forming the foam into
various structural shapes.
Prior to being included in the curable foamable formulation of the
present invention, the filler particles are desirably subjected to
a pretreatment process. Desirable pretreatments of the particles
may comprise grinding to a particle size distribution consistent
with that of fly ash or red mud, drying, as described below for red
mud, or preloading, which may be carried out as a pretreatment step
for particles like fly ash.
Commercially available red mud is dried for several hours at a
temperature above the boiling point of water, preferably around
230.degree. F., but under the maximum possible exotherm of the
system. The dried product is then pulverized to reduce the average
particle size, and screened, to reduce the variation in particle
size. Particles having an average particle size of 200 microns or
smaller are used.
The filling step does not appear to be time dependent, and the
particular placement of the reinforcing particles in part depends
on the type of metering, mixing, and dispensing equipment. In the
simplest case, the filling step comprises calculating a specific
weight of reinforcing particles based on the overall reactive
polymer weight, to establish a weight percent range (anywhere from
10% to 85%) preferably 60%; adding the weighed particles to either
the polyester polyol, diisocyanate or polyisocyanate, or both;
totally wetting out all reinforcing particles by shear mixing,
without inadvertently mixing the reactants; blending in any special
purpose reactive additive, e.g., a reactive flame retardant polyol,
a capped non-reactive polymer network to be further combined in an
IPN, etc.; and finally allowing air bubbles, which have been mixed
in, to escape from the two blends, so that massive instabilities
are not present when the reactants are foamed. Reinforcing
particles containing water as a blowing agent, or which are to be
preloaded with a blowing agent reactive with isocyanates should
not, in general be added to the isocyanate component, but should
instead be premixed with the polyester polyol component.
Preloading of the reinforcing particles with blowing agent may
occur either prior to of during the filling step. Prior preloading
involves merely mixing the particles with blowing agent until the
particles are at least partially wetted out, then adding the
preloaded particles to the filling step. Preloading during the
filling step involves, for example, adding the particles to the
polyester polyol without mixing, adding blowing agent in proximity
to the particles, and mixing. Prior preloading is desirable when
the viscosity of the blowing agent is significantly greater than
that of the polyester polyol or isocyanate.
Another important aspect of the reinforcing particles is that each
allows the resin forming system sufficient time to foam. The
reinforcing particles, because they either contain a blowing agent
naturally or as a result of having been preloaded, release
entrained water during the polyurethane reactions, thereby foaming
the resin. With pure silica, or with thixotropic additions to
thicken the reacting resins, it was not possible to foam this
system with either water or Freon 11, formerly the industrial
standard blowing agent.
Without being bound by any theory, it is believed that the
reinforcing particles used in the present invention release water
at different energy levels during the above-mentioned reaction by
at least two mechanisms.
Particles like red mud and various clays contain combined water or
other liquid which is bound at various levels of the particle
structure, and with varying strength. This liquid functions as a
blowing agent that is released from the particle over a range of
energies during the foaming and curing reactions. The exothermic
heat of reaction frees loosely bound liquid first. As the reactions
progress, the urethane-forming exotherm causes the overall
temperature of the mixture to rise; the foaming mass gets hotter,
and more tightly held liquid is freed from the particles to the
reaction. This progressive release with the increasing energy of
the curing reaction provides blowing agent, and therefore foaming,
throughout the course of the curing process. When the blowing agent
is water, the particle acts as a reactant, a filler, and as a
catalyst to speed up the curing reaction. The cure time of foams
produced in accordance with the present invention is generally
under four minutes.
Particles like fly ash require the addition of a small amount of
blowing agent to preload the particulates with blowing agent which
is then released slowly as the retarded curing reaction proceeds.
While the release mechanism is not completely understood, it is
believed that a variety of blowing agent release mechanisms may
occur. For example, the blowing agent may combine with chemicals in
the particle which can be released later (e.g., water may combine
with oxides (CaO, MgO, Na.sub.2 O, K.sub.2 O, and possibly others)
in fly ash to form a range of reactive hydroxides); the blowing
agent may become trapped in the spongy, foamy cenospheres and later
released by the curing reaction; the blowing agent may be adsorbed
on diverse carbon particles present in the reinforcing particles,
giving a usable release range; or the blowing agent release may be
influenced by the presence of organic residues, polycyclic aromatic
hydrocarbons (PAHs), or polynuclear aromatic hydrocarbons (PNAs).
The release range of the blowing agent in the particles may be the
result of two or more of these mechanisms. In any case, the
addition of small amounts of blowing agent interacts with an
organic or inorganic structure in the reinforcing particles in a
manner that allows it to be released as required by the foaming and
curing reaction in a manner similar to that of clays or red mud, as
described above. The preloaded particle therefore serves at least
two functions: entraining and releasing the blowing agent for
foaming during the reaction, and reinforcing the continuous
phase.
The mixing of the filled reactants is time dependent, and requires
an efficient shear mixer to homogeneously blend the thickened,
filled materials. As examples of mixing times, with treated red mud
filled reactants, the mixing time available before the material
begins to foam is approximately sixty seconds. Fly ash with added
water gives a larger window of production flexibility, in that at
least three or four minutes are available for the mixing step
before the material is poured into a mold. In addition, the
crosslinking reaction which occurs after the first sets of
reactions forming urethane and urea can be delayed to the point
where additional processing steps can be accomplished on the
partially cured mass.
Economic benefits related to machine capacity and mold filling
requirements result from using a filler system having relative
amounts of either or both reinforcing particles that can be
tailored to control curing rates. Specifically, smaller, less
expensive metering, mixing, and dispensing equipment can be used to
fill molds that would normally require larger machines due to a
fixed, short reaction time after mixing.
As previously explained, it is difficult to foam a highly
crosslinkable polyester material. The reasons relate to the loss of
flexibility of the binder phase caused by polyester crosslinking,
and to the generation of exothermic heat of reaction, which causes
additional expansion, resulting in additional stresses against the
binder wall. Three other reactions detrimental to foam generation
are avoided by the use of fly ash and/or treated red mud as
reinforcing particles. First, the reinforcing particles of the
present invention are, for the most part, hard microspheres, not
sharply pointed or angular particles. These reinforcing particles
do not effectively raise the stress during the foaming process, and
spread the stress during hardening over a greater portion of the
binder, resulting in less tendency to rupture cell walls. Second,
since there can be a wide range of spherical particle sizes, more
efficient particle packing occurs in the binder walls. The packing
in the cell walls is at least tri-modal, and even the largest
particles usually have a diameter less than one-third of the cell
wall thickness. This reduces the overall effect of the stresses on
the binder walls caused by the shrinkage that occurs as the binder
is curing. Third, the chemistries of the reinforcing particles,
especially fly ash and treated red mud, allow foaming to occur over
a long critical period, during which the binder structure is curing
to the point where it has enough strength to maintain the void
structure until binder hardening predominantly utilizing the
polyester crosslinking reaction locks the structure into place.
The foaming process occurs in steps which are initiated as soon as
the reactants are mixed. The first step is the exothermic urethane
reaction. The heat generated begins to free the blowing agent
associated with the reinforcing particles, for example the water
associated with treated red mud or preloaded fly ash. The most
loosely bound blowing agent, for example loosely bound water or
free water, in the system reacts to form a transient carbamic acid
and carbon dioxide. The carbamic acid yields an aniline derivative
which further reacts with isocyanate groups to produce a urea
linkage. This reaction is very exothermic, and provides the heat
energy necessary to free more tightly bound blowing agent from the
reinforcing particles.
The free radical initiated copolymerization of the reactive monomer
and the unsaturated polyester polyol occurs after the foaming and
urethane reactions are well underway. This crosslinking reaction
significantly hardens the binder, and ideally occurs after the
foaming reaction is complete. The crosslinking reaction is the
final curing step and comprises reacting the ethylenically
unsaturated groups of unsaturated polyester-polyurethane and the
reactive monomer, which serves both as a diluent for the reaction
system and as a curing agent.
The steps of foaming and prestabilizing the filled foam occur
basically during polyurethane (and polyurea) formation, which are
among the first set of reactions resulting from the reaction of the
diisocyanate or polyisocyanate with the unsaturated polyester
polyol and released water.
The present invention is now described in more detail by referring
to the following Examples and Comparative Examples, which however
should not be construed to be limiting the scope of the present
invention.
The hybrid materials used for the examples were part of the two
component hybrid system of unsaturated polyester/polyurethane
manufactured by Cook Components and Polymers (Freeman Division).
There are three basic materials that are currently produced for
resin transfer molding that make up the Interpol systems. These
three basic materials each designated by two numbers are as
follows: 35-5116/35-5205, 35-5118/35-5205; and 35-5124/355205.
The component common to all three systems is designated Interpol
35-5205. This is a medium functionality MDI Isocyanate. The NCO
content of this polymethylene polyphenyl isocyanate is 32 percent.
Prior to mixing, a blend is made between the Interpol 5205 and
Interpol 31-0070. Interpol 31-0070 is a 50/50 weight percent blend
of benzoyl peroxide catalyst and an inert material, tricresyl
phosphate, which is included for safety reasons.
The designations 35-5116, 35-5118, and 35-5124 refer to materials
that generate a more urethane acting cured material. This is
accomplished by adding higher levels of saturated polyester polyol
which is compatible with the unsaturated polyester polyol
containing hydroxyl terminations. The resin solution is
approximately 75 percent solids and 25 percent styrene monomer. In
general, as the amount of saturated polyester polyol decreases, the
amount of styrene increases, as does the crosslink density. In
addition, since the amount of Interpol 5205 is always 27/129 of the
total mix, the hydroxyl number of the diluted solutions must be
constant for 35-5116, 35-5118, and 35-5124. This implies the
hydroxyl number of the saturated polyol is equivalent to the
hydroxyl number of the unsaturated polyester polyol with hydroxyl
terminations.
Specifically, Interpol 35-5118 contains an unsaturated polyester
polyol with hydroxyl terminations, approximately 25 weight percent
styrene, standard organometallic catalysts for the urethane
reaction, and a tertiary amine promoter; other chemicals used in
the examples include PHT4-DIOL, a tetrabromophthalic anhydride diol
which can be used as a flame retardant and which can be foamed. It
can also be foamed independent of the filled hybrid foaming
process. Other compounds, including surfactants, e.g. LF443,
produced by Air Products, reactive liquids containing flame
retardants, and colorants may be included in the examples to
provide established functions.
One of the main components of the Interpol system hybrid is formed
by the production of an unsaturated polyester polyol containing
hydroxyl sites and reaction thereof with styrene monomer and
diphenylmethane diisocyanate in the presence of a benzoyl peroxide
catalyst. The end product of this reaction is a polymer hybrid
containing approximately thirty percent polyurethane and seventy
percent polyester. The polyurethane reaction occurs first, and is
followed by the free radical initiated crosslinking of the
unsaturated polyester polyol with the styrene monomer. The sequence
of the reactions is important to the foaming reaction.
EXAMPLE 1
In vessel 1, 775 grams of an unsaturated polyester polyol
composition ("Interpol 5118", Cook Composites and Chemicals, Inc.)
were blended with 428 grams of treated red mud. In vessel 2, 209
grams of an isocyanate compositions ("Interpol 5205", Cook
Chemicals and Composites) were blended with 15 grams of benzoyl
peroxide paste. The contents of vessel 2 were added to vessel 1 and
thoroughly mixed. The curing reaction was accelerated, a foam of
homogeneous small bubbles was produced having a foam density of 31
pounds per cubic foot, and a very lightweight filler unsaturated
polyester polyol/polyurethane hybrid foam was produced.
EXAMPLE 2
In vessel 1, 775 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 1222 grams of treated
red mud and 2 grams of water. In vessel 2 209 grams of an
isocyanate composition (Interpol 5205) were blended with 15 grams
of benzoyl peroxide paste. The contents of vessel 2 were added to
vessel 1 and thoroughly mixed. The curing reaction was further
accelerated, and a foam of homogeneous small bubbles was produced
with a foam density of 40 pounds per cubic foot. On curing, a very
lightweight filled unsaturated polyester/polyurethane hybrid foam
was produced.
EXAMPLE 3
In vessel 1, 625 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 977 grams of Type F
fly ash, 6 grams of water, and 2 grams of LK443 surfactant. In
vessel 2, 168 grams of an isocyanate composition (Interpol 5205)
were blended with 12.5 grams of benzoyl peroxide paste. The
contents of vessel 2 were added to vessel 1 and thoroughly mixed.
The curing reaction was significantly retarded, and a foam of
homogenous small bubbles was produced with a foam density of 38
pounds per cubic foot, and a highly filled unsaturated
polyester/polyurethane hybrid foam resulted.
EXAMPLE 4
In vessel 1, 1705 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 2688 grams of treated
red mud and 18 grams of water. In vessel 2, 460 grams of an
isocyanate composition (Interpol 5205) were blended with 44 grams
of benzoyl paste. Entrapped air was allowed to escape for five
minutes from each blend. The contents of vessel 2 were added to
vessel 1 and thoroughly mixed. The mixture was poured into a mold
constructed to make a tee beam that can be evaluated according to
ATM C78 for flexure testing concrete by the third-point loading
method.
The material produced a foam of homogenous small bubbles, having a
density of 54 pounds per cubic foot, and a lightweight foamed
unsaturated polyester/polyurethane hybrid structure in the form of
a tee beam twenty inches long resulted. Further, when the beam was
tested by a qualified outside testing laboratory to ASTM C78
specification, the very surprising result that the beam failed
under an applied load of 9350 pounds, which equates to a
compressive strength of 6545 pounds per square inch and a tensile
strength of 2805 pounds per square inch, was obtained.
EXAMPLE 5
In vessel 1, 1162 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 1833 grams of treated
red mud, and 6 grams of water. In vessel 2, 314 grams of an
isocyanate composition (Interpol 5205) were blended with 23 grams
of benzoyl peroxide paste. Entrapped air was allowed to escape for
five minutes. The contents of vessel 2 were added to vessel 1 and
thoroughly mixed. The mixture was poured into a mold constructed to
make a tee beam that can be evaluated according to ASTM C78
procedures for flexure testing concrete by the third point loading
method.
The material produced a foam of homogeneous small bubbles, having a
density of 31 pounds per cubic foot and a filled lightweight foamed
unsaturated polyester polyol/polyurethane hybrid structure in the
form of a tee beam twenty inches long resulted. Further, when the
beam was tested by a qualified outside testing laboratory to ASTM
C78 specification, the surprising result that the beam failed under
an applied load of 3850 pounds which equates to a compressive
strength of 2695 pounds per square inch and a tensile strength of
1155 pounds per square inch, was obtained.
EXAMPLE 6
In vessel 1, 1162 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 1833 grams of Type F
fly ash and 20 grams of water. In vessel 2, 314 grams of an
isocyanate composition (Interpol 5205) were blended with 23 grams
of benzoyl peroxide paste. Entrapped air was allowed to escape for
five minutes. The contents of vessel 2 was added to vessel 1 and
thoroughly mixed. The mixture was poured into a mold constructed to
make a tee beam that can be evaluated according to ASTM C78
procedure for flexure testing concrete by the third point loading
method.
The mixed material produced a foam of homogeneous small bubbles.
The foam had a density of 32 pounds per cubic foot and a filled
lightweight foamed unsaturated polyester polyol/polyurethane hybrid
structure in the form of a tee beam twenty inches long resulted.
Further, when the tee beam was tested by a qualified outside
testing laboratory to ASTM C78 specification the surprising result
that the beam failed under an applied load of 3750 pounds, which
equates to a compressive stress of 2625 pounds per square inch and
a tensile stress of 1125 pounds per square inch, occurred.
EXAMPLE 7
In vessel 1, 1162 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 1833 grams of Type F
fly ash, and 11.3 grams of water. In vessel 2, 314 grams of an
isocyanate composition (Interpol 5205) were blended with 23 grams
of benzoyl peroxide paste. Entrapped air was allowed to escape for
five minutes. The contents of vessel 2 were added to vessel 1 and
thoroughly mixed. The mixture was poured into a mold constructed to
make a tee beam that can be evaluated according to ASTM C78
procedures for flexure testing concrete by the third point loading
method.
The mixed material produced a foam of homogeneous small bubbles.
The foam had a density of 37 pounds per cubic foot and a filled
lightweight foamed unsaturated polyester polyol/polyurethane
structure in the form of a tee beam twenty inches long resulted.
Further, when the tee beam was tested by a qualified outside
testing laboratory to ASTM C78 specification, the surprising result
that the beam failed under an applied load of 4400 pounds, which
equates to a compressive strength of 3080 pounds per cubic inch and
a tensile strength of 1320 pounds per cubic inch, occurred.
EXAMPLE 8
In vessel 1, 100 grams of a flame retardant diol (PHT4-DIOL) were
blended with 1 gram of water. Vessel 2 contained 50.3 grams of an
isocyanate composition (Interpol 5205). The total contents of
vessel 2 were added to vessel 1 and thoroughly mixed. A
polyurethane, polyurea foam was produced.
EXAMPLE 9
In vessel 1 581 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 112 grams of a flame
retardant diol (PHT4-DIOL) and 1108 grams of treated red mud. In
vessel 2, 213 grams of an isocyanate composition (Interpol 5205)
were blended with 11.6 grams of benzoyl peroxide paste. The
contents of vessel 2 were added to vessel 1 and thoroughly mixed.
The mixed material produced a foam of homogeneous small bubbles,
having a density of 31 pounds per cubic foot and a filled light
weight structure of a foamed, unsaturated polyester
polyol/polyurethane hybrid modification was produced. It is
believed that reactive diol addition modified the chain extension
and crosslinking of the hybrid, thereby making the hybrid structure
more complex, or that this addition results in the formation of a
polyurea/polyurethane network instead of crosslinking to the
hybrid, thus forming an IPN structure, or that the addition
provides an unknown percentage of both the modified hybrid or IPN
structure. The end result is that flame retardant contained within
the PHT4-DIOL is locked in place by either molecular bonding, chain
entanglement, or both, and cannot migrate to the voids and bleed
out over time. In addition, the added material provides an
additional segment or dispersed phase for strengthening.
EXAMPLE 10
A series of filled hybrid foams were made using conventional meter,
mixing, and dispensing equipment, containing two feed vessels or
tanks. The first tank contained 11 lbs. of Interpol 035-5118, 11
lbs. of Interpol 035-5124, 2.2 lbs. of Great Lakes PHT-4DIOL, 1.35
lbs. of Air Products DC 193 surfactant, 50 lbs. of Type F fly ash,
0.5 oz. of UL 33 catalyst, and 7 oz. of water. The second tank
contained 16 lbs. of 035-5205 (polyisocyanate) and 1 lb. of
031-0070 (benzoyl peroxide in an equal amount by weight of
tricresyl phosphate). These two mixtures of material were pumped to
a mix head, mixed, and dispensed into various molds. The foamed
parts were postcured for 2 hours at 220.degree. F.
From one plate were cut two samples 1 in..times.1 in..times.0.5 in.
(thickness). One of the samples had four exposed cut sides, and had
a dry weight of 5.85 grams. The second sample was sanded on its two
skin sides to give 6 exposed foam surfaces, thereby approximating a
core structure. This sample weighed 5.4 grams.
Both samples were immersed in water by weighting to the bottom of a
container (weighting was necessary because the density of the
samples was 55 pcf). A vacuum was applied to the samples for 20
minutes. The samples were then removed from the water, surface
dried, and weighed again. The weight of the first and second
samples after this water treatment was 5.9 grams and 5.52 grams,
respectively. The weight of water drawn into the sample by the
vacuum, divided by the weight of the sample with water was at least
98%, indicating that the foams contain well over 90% closed
cells.
Comparative Example 1
In vessel 1, 775 gams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with two grams of water.
In vessel 2 209 grams of an isocyanate composition (Interpol 5205)
were blended with fifteen grams of benzoyl peroxide paste. The
contents of vessel 1 were added to vessel 2 and thoroughly mixed.
The curing reaction was retarded, and some bubbles were released to
the surface. No foam was produced, but a polyurethane/unsaturated
polyester hybrid solid was obtained.
Comparative Example 2
In vessel 1, 542 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 15 grams of Freon 11,
and two grams of LK443 surfactant. In vessel 2 146 grams of an
isocyanate composition (Interpol 5205) were blended with 10.9 grams
of benzoyl peroxide paste. The contents of vessel 1 were added to
vessel 2 and thoroughly mixed. The curing reaction was not
effected, and some bubbles were released to the surface. No foam
was produced, but a polyurethane/unsaturated polyester hybrid solid
resulted.
Comparative Example 3
In vessel 1, 775 grams of an unsaturated polyester polyol
composition (Interpol 5118) were blended with 500 grams of ultra
fine sand (particle diameters equivalent to the particle size of
fly ash or treated red mud of the present invention) and 2 grams of
water. In vessel 2,209 grams of an isocyanate composition (Interpol
5205) were blended with 15 grams of benzoyl peroxide paste. The
contents of vessel 2 were added to vessel 1 and thoroughly mixed.
The viscosity of the mixture was greater than that of example 4 but
slightly less than that of example 5. Some bubbles were released to
the surface, but no foam was produced, and an unsaturated
polyester/polyurethane hybrid solid was produced.
The foamed products of the present invention may be used, e.g., as
building materials, e.g., as lightweight roofing materials (e.g.,
slates or tiles), as decorative or architectural products, as
outdoor products, as low cost insulation panels, as fencing, as
lightweight buoyant or corrosion-resistant marine products, etc.,
by forming the foamed resin in a mold of suitable size and shape,
and then using the molded product in an art-recognized way.
Moreover, the foamed products of the present invention may be used
as a lightweight, foamed insert, optionally having a partially
embedded random mat glass structure, in subsequent casting
operations to produce a low cost, high strength composite
structure.
* * * * *